Geotechnical Monitoring for Safe Excavation of Large Rock Cavern: A Case

Study

A.Mandala, C. Kumar

b, A. Usmani

b and A. Nanda

b

aDepartment of Civil Engineering, VNIT-Nagpur, India

bEngineers India Ltd., New Delhi, India

E-mail: amandalthesis@yahoo.com, chandan@eil.co.in , altaf.usmani@eil.co.in, ananda@eil.co.in.

Abstract - The present study highlight the methods used to

monitor the geotechnical behaviour and

performance of the cavern during excavation in

order to verify and, if necessary, adjust the rock

support to ensure safe construction at every stage.

The present geotechnical monitoring practice for

underground structures involve convergence

monitoring with the help of optical targets and

rock mass displacement with help of bore hole

extensometers. More importantly it involve

detailed planning to finalize the position of each

monitoring instruments based on location and

orientation of geological features. Further it is

equally important to ensure proper recording of

monitoring data in order to analyze and take

immediate action in case of any adverse situation.

This requires a dedicated high end automated

software, which can record, analyse and produce

significant results out of large quantity of

recorded data which otherwise turns out to be

only ravage. Initially geotechnical monitoring was

carried out in recently excavated zone of cavern

on daily basis. Further based on continuous

monitoring data for at least one week, frequency

of monitoring is further decided. In most of the

cases the deformation of rock mass was quite less

compare to the alarming values which were

evaluated based on detailed design for different

rock classes.

Keywords -

Underground excavation, Cavern, Tunnel, Geotechnical

Monitoring

1 Introduction

This paper discusses in detail geotechnical

monitoring activity carried out during construction of

an underground unlined rock cavern complex for

storage of crude oil at western part of India. The total

storage capacity was 2.5MMT of crude oil. As four

numbers of rock cavern units were to be built, for the

ease of construction, the caverns were divided into

two parts. Each part consists of two U shaped storage

units with two legs. Each leg was extended almost

700 m, thus total length of cavern was around six

kilometres. This project involve the excavation of

vertical shaft for crude intake and out let, access

tunnel to facilitate excavation at required depth, water

curtain tunnel for continuous ground water recharge

and the large cavern for storage space. However,

present study only concentrates on the geotechnical

monitoring activity implemented inside the cavern as

it was most critical due to its large size and extent.

Each U shaped cavern unit (in plan) is designed with

30.0 m high and 20.0 m wide (in cross section) to

create the required storage space. On and average

cavern crown was 60.0 m below the ground surface

with a trend of 600/240

0.

As this construction involves lot of excavation

activity at different depth and direction, it was very

essential to ensure global stability of this zone along

with the stability of each structure. Any underground

excavation involves certain amount of geological

uncertainties. The more the extent of such excavation

more the uncertainties have to deal with. So, the

available option to handle such situation was

continuous geotechnical monitoring, Geological

assessment and suitable design provision to

incorporate different geological conditions during

excavation.

The support philosophy of all underground

openings within the project is based on staged

excavation, incremental installation of rock support

measures and verification by monitoring. In addition

robust design approached was followed to

The 31st International Symposium on Automation and Robotics in Construction and Mining (ISARC 2014)

accommodate modification of rock supports based on

actual characteristic of rock mass, thus leading to cost

effective and practical rock support.

2 Geological Assessment of Site

Geological and geotechnical investigation was

carried out in three phases during the period 2005 to

2010. In total 20 nos of bore holes were drilled in

vertical and some of them in inclined orientation in

each phases. Initially six numbers of boreholes were

drilled in the year 2005 at some specific locations

based on the information available from geophysical

survey as well as out crops observed during site visit.

The data obtained from first phase survey was used to

develop tentative Geological map of this site

projecting the extension and orientation of

different features. Based on this map, second phase of

investigation was planned which includes another six

bore holes to ensure the possibility of projected

geological features. Finally detailed geological map

was developed after completion of third phase

investigation which includes additional drilling of

eight numbers of bore holes. This geological map

kept on updating as excavation progress

incorporating the geological information obtained

from excavated zone. Further this map was used to

plan the location of optical targets and bore hole

extensometer along cavern section for continuous

monitoring of critical area.

2.1 Geology

This area was located within ’Peninsular

Gneisses’ (M.S. Krishnan, (1953). The Peninsular

Gneisses are characterized by heterogeneous mixture

of different types of granite intrusive into the

schistose rocks after the latter were folded and

crumpled. Within the project area, Peninsular Gneiss

is by far the most represented rock type. However,

types of granite are also found in some places. The

details of the structural discontinuities within the rock

mass as determined from the mapping reveal 3

significant joint sets, 1 minor joint set and the

foliation as show in Table 1.

Generally it was expected that very poor to poor

quality rock will be encountered up to a depth of

approximately 3 to 5 m below ground level, whilst

fair and good rock is anticipated greater than 20 to 30

m below ground level. The local geological

conditions of the project site are characterized by

three geotechnical relevant rock mass layers of

varying thickness.

Table 1: Observed Geological features

Features Dip Direction Dip.

Joint set 1 070 85

Joint set 2 100 85

Joint set 3 200 85

Minor Joint set 045 45

Foliation 020 85

The top layer is varying in thickness and consists of

residual soil and lateritic. Immediate second layer is

characterized by weather, jointed and fractured rock

with boulders with varying thickness and bottom

layer is hard fresh and massive rock. Most of the

project component is located in the bottom layer (bed

rock) except initial portion of access tunnel and shaft.

No major tectonic event has occurred in this zone

subsequent to formation of these rocks.

2.2 Geotechnical Assessment

The main geotechnical failure modes expected in

the caverns of this storage complex are sliding of

blocks/wedges along discontinuities, toppling and

rotational failures and the development of overbreak

in and around zones of fractured and weather rock.

Weathering and ground water are deemed to have had

little influence on the regional rock mass condition.

The main influencing factor is the quantity and

quality of discontinuities. A number of small fault

like features were recorded during the investigation.

However, it was expected to have little impact of

these faults on rock mass behaviour in most cases. No

major pre existing inactive and active mass

movements were detected. However, this area is

classified as Zone-III with seismic coefficient of

about 0.04g as per Seismic Zone map of India (IS

1893).

Relatively high horizontal stress (SH) in the range

of app. 6 to 9 MPa was envisaged along the cavern

roof. For the typical vertical stress at the site of about

4 MPa, corresponding approximately 50 to 80m of

overburden, the typical values of the in-situ stress

ratios was in a range of 2.2 MPa.

3 Geotechnical Monitoring Plan

In this project two differ types of instrumentations

were used to measure the deformation i.e.

POSTER PAPER

convergence monitoring by optical targets and rock

mass deformation by extensometer. Convergence

monitoring was carried out along the cavern section.

However, deformation measurement by extensometer

was only limited to geological hot spot as observed

during investigation and subsequently substantiated

during the excavation of other components (access

tunnel and water curtain tunnel) of this project,

specifically from the excavation of water curtain

tunnel which was located just 20.0 m above the

cavern crown.

3.1 Optical Targets

The deformation monitoring of excavation

surfaces of cavern using 3D measurement of optical

targets (in x-y and z direction) was the main

geotechnical monitoring method in order to assess the

rock mass behaviour during excavation.

Optical targets were fixed to reference points

through bolting to the rock surface. The bolt was

installed through a drill hole of diameter 25 mm upto

a depth of 220 mm from rock surface. Then bi reflex

target was fitted to the installed bolt with the help of

the screw. Monitoring section within the caverns are

typically arranged at every 25.0 m of interval with

five targets within the top heading (one in crown and

two at each side) and 4 targets along each side wall as

shown in Fig. 1. However, additional section of

optical targets was installed based on observed

geological features in updated geological map.

Fig. 1: Cavern cross section with optical targets and

excavation stage.

The dotted line in the cross section of cavern

shows the excavation stage of each bench. Initially

pilot tunnel was excavated which was further

extended by side slashing to complete the heading

excavation. Similarly each bench excavation is also

associated with side slashing to complete each bench

thus total three bench excavations were carried out.

All three optical targets at the crown location were

installed immediately after the completion of

necessary support activity in pilot tunnel and other

two targets at heading were installed after completion

of first bench excavation. The targets at the wall were

installed after completion of subsequent bench

excavation. Initially at few locations, the damage of

optical targets was reported during first bench

excavation. Therefore, necessary precaution was

taken to protect the targets by removing it from the

bolt during blasting activity and placed thereafter.

3.2 Extensometer

Extensometer was installed in drilled boreholes

from the invert of water curtain tunnel at some

geologically critical locations as identified from

updated geological map. This water curtain tunnel is

located just 20.0 m above the crown of the cavern

which will be filled with water during operation to

ensure continuous flow of water around caverns to

maintain require hydrostatic pressure around the

cavern for confinement of crude oil. This tunnel is

extended along the cavern length.

At each location two different extensometers were

installed toward the cavern on either side of the water

curtain tunnel as shown in Fig. 2. Extensometer was

installed in drilled boreholes with three point

instrument at 5.0 m interval thus maximum length of

20.0 m and furthest point is approximately 5.0 m

away from cavern roof. This will monitor the rock

mass movement at crown of the cavern which was

envisaged as most critical part from stability point of

view.

Each extensometer rod was grouted where the rod

end is located in rock to develop strong bonding

between the rod and surrounding rock mass. Thus

minimize the chances of slippage between

extensometer rod and surrounding rock. The head of

the instrument was housed within a steel protection

cap to avoid disturbance and damage from different

construction activity. The sole purpose of these

extensometers was to monitor the rock mass

behaviour during construction.

Once the cavern was fully excavated and its

stability was further ascertained through the

stabilized extensometer monitoring data, the

instrument was abandoned and all void within the

instrument was grouted with cement grout to avoid

any potential passageway of water towards the cavern

crown.

It is usually works based on the assumption that

the deepest anchor is in stable ground and any change

in anchor spacing is interpreted as rock mass

The 31st International Symposium on Automation and Robotics in Construction and Mining (ISARC 2014)

movement. Here, the topmost anchor point (close to

water curtain tunnel) was considered as in stable

ground and will indicate any relative movement of

rock in cavern crown during cavern excavation which

will be recorded in it’s head assembly.

Fig. 2: Location and extent of Extensometer

from Water Curtain Tunnel

4 Geotechnical Monitoring Procedure

Monitoring team comprises Project manager,

Shift Manager, Site Engineer and Surveyor worked

till the end of construction which completed in the

year 2013 involving the underground excavation of

34.9 Lakh cum rock without any accident related to

stability of rock.

4.1 Convergence Reading

Reading from optical targets was taken with the

help of total station survey. The control points were

fixed with reference to the original project co-

ordinates at every section where the targets were

fixed. First set of readings shall be zero readings of

the targets. Data of all the readings were stored in the

memory module of total station automatically and

then down loaded it to the computer for further

processing.

4.2 Extensometer Reading

Grouted anchored type borehole extensometer

composed of head assembly, vibrating wire

displacement sensors, connecting rod assembly and

anchor or reinforcement bar were installed. Extension

rods were installed in to the bore hole up to the

required depths. Then the extensometer sensors were

fixed after four days of grouting and initial reading

were taken from read out unit. Data were stored and

plotted to find the trend of rock mass behaviour.

4.3 Monitoring Frequency

The data manually obtained from optical targets

and extensometers were entered and saved

electronically in spreadsheet and plotted with time

(frequency).

Table 2: Monitoring frequencies for convergence

monitoring by Optical targets.

Instrument Frequency Condition-1 Condition-2

Optical

Targets

Once per

day

Within

30.0m from

the

excavation

face

The

differential

deformation

between the

current and

the previous

reading is

more than

5.0 mm.

every other

day

within 30.0m

from the

excavation

face

The

differential

deformation

between the

current and

the previous

reading is

more than

2.0 mm.

Once every

week

between

30.0m and

60.0m from

the

excavation

face

The

differential

deformation

between the

current and

the previous

reading is

larger than

monitoring

accuracy

once per

month

excavation

face is more

than 60.0 m

away

The

differential

deformation

between the

current and

the previous

reading is

within

monitoring

accuracy

POSTER PAPER

These frequencies were mentioned in Table 2 & 3

with different condition. However, this frequency

was further modified based on actual behaviour of

rock mass observed after plotting and interpreting the

recorded data. Observed data as per given frequency

was plotted and uploaded to the centralize server and

all concern person could have the access to the server

whenever required. This was followed by the

interpretation of all monitoring data by design

engineer to assess the overall stability at certain stage

to decide and verify further excavation strategy.

Table 3: Monitoring frequencies for Extensometers.

Instrument Frequency Condition-1 Condition-2

Extensometer

Once per

day

Excavation

face in

cavern

gallery is

within 40.0

m of the

instrument

The

differential

deformation

between the

current and

the previous

reading is

still more

than 5.0 mm

Once

every

week

Excavation

face in

cavern

gallery is

more than

40.0 m away

from the

instrument.

The

differential

deformation

between the

current and

the previous

reading is

larger than

monitoring

accuracy.

Once per

month

Excavation

face in

cavern

gallery is

more than

40 m away

from the

instrument.

The

differential

deformation

between the

current and

the previous

reading is

within

monitoring

accuracy.

5 Monitoring Results and Discussion

In such large projects, compilation and recording

of monitoring data is an important aspect and cannot

be left to simple practice of sheets and tables.

Presently with the advent of technology, this filed of

data management has also witnessed lot of

upgradation and automation. Therefore in this project

also, all monitoring data were managed through a

dedicated geo monitoring software, which works as a

tunnel information system for continuous monitoring

by concerned person at site as well as design office.

Deformation value as observed in optical targets was

plotted in all three direction (two horizontal and

vertical) with respect to time of observation.

Similarly, extensometer reading of three anchor

points was also plotted with respect to time of

observation. All these results were compared

regularly in reference with different limit value.

5.1 Deformation Limit

Monitoring values were used to evaluate the rock

mass condition by comparing measurement results

against expected soil/rock deformation. Different

monitoring limit values were introduced to categorise

measurements in terms of their severity. This limit

was developed from the expected deformation in

detailed design calculation and functioning and

maintenance of the structure. In the detailed design

calculation, rock mass as observed in this area was

classified broadly in three classes as per their Q

values i.e. Class 1. Good and Very Good Rock, 2.

Fair Rock and 3.Poor Rock and expected deformation

were defined for each of them. For all these three

classes two limits were fixed namely “trigger level”

and “allowable level”. Trigger level is defined as the

permitted maximum displacements of a particular

structure or area, which is critical to the safety,

functioning of the structure. It was considered as 80%

of design value.

Table 4: Monitoring limit values for different rock

Class

Rock Class

(Q-value)

Top Heading Benching Trigger

(mm)

Allowable

(mm)

Trigger

(mm)

Allow

able

(mm)

Very Good

and Good 5.0 10.0 5.0 8.0

Fair 5.0 10.0 5.0 7.0

Poor 24.0 42.0 13.0 22.0

Whereas allowable level, is the maximum limit which

should not exceed in any case and this was set at

140% of the design value. Absolute values as

considered in this project for different rock class at

various stages of excavation are reported in Table 4.

The 31st International Symposium on Automation and Robotics in Construction and Mining (ISARC 2014)

5.2 Interpretation

In most of the case, the observed deformation in

geotechnical monitoring data observed from optical

targets was well within the trigger limit. There was

not a single incident reported where the deformation

exceed the allowable limit. However, at few locations

sudden increase in deformation was observed due to

the major excavation activity in that vicinity. When

the deformation value exceed the trigger value at

some section of the cavern, that location was visually

inspected by engineer to check the possible distress in

terms of increased seepage or any crack in the

installed shotcrete to allow further excavation.

Fig. 3: Deformation plot for vertical and

horizontal direction upto completion of project

Typical deformation of cavern section plotted in Fig.

3 for poor rock condition where relatively higher

deformation was observed.

Fig. 4: Extensometer reading at poor rock

condition

Similar trend of deformation was also observed in

Extensometer reading as presented in Fig. 4. In this

case increase in the deformation was observed during

the pilot tunnel and side drift at heading excavation.

Afterward there was no significant increase in

deformation due to subsequent bench excavation. In

both the measurement, the deformation values in poor

rock condition were remarkably low compare to the

trigger value at different stage of excavation. This

may be due to the conservative design approach as

followed in this project for poor rock class. However,

the incident of poor rock class encountered was less

than 5% as compare to total excavation length.

6 Observation and Comments

This paper was specifically developed to highlight

the systematic approach followed for large cavern

excavation to minimize the risk of rock fall due to

sudden change in geology. Initially, three stage

geological investigations were quite efficient to

understand the rock mass character more accurately.

Particularly it helped to minimize the occasion of

geological surprises involved in underground

excavation. Moreover, continuous design updation

activity employing high end dedicated software’s

based on latest geological information along with

geotechnical monitoring helps to use rock support

system more efficiently and economically. However,

geotechnical monitoring method using optical targets

need to be improved for such large excavation. It was

observed in many occasion during the excavation that

the total station survey to take the reading suffer from

accuracy due to disturbance from construction

activity. The initial deformation which may have

occurred immediately after excavation can’t be

recorded in optical targets measurement. This need to

be addressed in future study by cost effective

automatic instrumentation. Thus monitoring data will

be more accurate and will definitely minimize the

scope of human error involved in recording and

uploading such huge data. Also the application of

mobile technology can help to keep alert all

concerned round the clock.

References

[1] Design Package for Cavern Storage

4923/REP/PUA/0310, Engineers India Ltd., New

Delhi, India.

[2] Geotechnical Monitoring and Instrumentation,

4923/DSB/PUA/0014 Engineers India Ltd., New

Delhi, India.

[3] Krishnan, M. S. The structural and tectonic

histo-y of Jndia ~Mem, Geol, Surv, India,

vol.81. p.1-93.1953.

[4] I.S. 1893 part-1; Indian Standard Code for

Earthquake Intensity.

POSTER PAPER